English

Noncommutative $L_p$-differentiability and trace formulae

Operator Algebras 2026-02-18 v2 Mathematical Physics Functional Analysis math.MP Spectral Theory

Abstract

Let M\mathcal{M} be a semifinite von Neumann algebra equipped with a normal faithful semifinite trace τ\tau, and let Lp(M)L_p(\mathcal{M}) denote the associated noncommutative LpL_p-space for 1<p<1<p<\infty. Let nNn\in\mathbb{N} and let a,ba, b be τ\tau-measurable self-adjoint operators such that bLp(M)Lnp(M)b\in L_p(\mathcal{M})\cap L_{np}(\mathcal{M}). For a function fCn(R)f\in C^n(\mathbb{R}) whose derivatives f(k)f^{(k)} are bounded for 1kn1\le k\le n, we prove that the map ϕ:tRf(a+tb)f(a)\phi:t\in\mathbb{R}\mapsto f(a+tb)-f(a) is nn-times differentiable in the Lp\|\cdot\|_{L_p}-norm. This strengthens the corresponding result of de Pagter and Sukochev for p2p\neq 2 and extends it to higher-order derivatives. In addition, if f(n)C0(R)f^{(n)}\in C_0(\mathbb{R}) or bMb\in \mathcal{M}, then ϕ(n)\phi^{(n)} is continuous on R\mathbb{R}. Consequently, we extend the Potapov--Skripka--Sukochev higher-order trace formula from bounded LnL_n-perturbations to not necessarily bounded perturbations in Ln(M)Ln2(M)L_n(\mathcal{M})\cap L_{n^{2}}(\mathcal{M}). Moreover, we show that this trace formula holds for a broader class of admissible functions than the classes previously considered in the literature.

Keywords

Cite

@article{arxiv.2602.10694,
  title  = {Noncommutative $L_p$-differentiability and trace formulae},
  author = {Arup Chattopadhyay and Clément Coine and Saikat Giri and Chandan Pradhan},
  journal= {arXiv preprint arXiv:2602.10694},
  year   = {2026}
}

Comments

We have corrected several typographical errors; for example, the $\tau$-measurability of $a$ and $b$ was previously omitted in some places. In addition, we have relaxed the assumptions on the perturbation when proving the continuity of the $n$-th derivative of $f(a+tb)$ and when establishing the trace formula

R2 v1 2026-07-01T10:31:36.584Z